Dynamical properties of Au from tight-binding molecular-dynamics
  simulations

A. F. Voter; C. M. Goringe; D. A. Papaconstantopoulos; D. A. Papaconstantopoulos; D. A. Papaconstantopoulos; D. J. Steinberg; D. Singh; E. A. Owen; F. Kirchhoff; F. S. Khan; G. C. Kallinteris; G. J. Ackland; G. Simmons; J. P. Perdew; J. W. Lynn; K.-M. Ho; M. J. Mehl; M. J. Mehl; M. J. Mehl; M. J. Mehl; N. Binggeli; N. I. Papanicolaou; N. I. Papanicolaou; O. K. Andersen; R. N. Silver; S. H. Yang; W. B. Pearson; W. Kohn; Y. S. Touloukian; Y. Waseda

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Dynamical properties of Au from tight-binding molecular-dynamics simulations

Authors: A. F. Voter
C. M. Goringe
D. A. Papaconstantopoulos
D. A. Papaconstantopoulos
D. A. Papaconstantopoulos
D. J. Steinberg
D. Singh
E. A. Owen
F. Kirchhoff
F. S. Khan
G. C. Kallinteris
G. J. Ackland
G. Simmons
J. P. Perdew
J. W. Lynn
K.-M. Ho
M. J. Mehl
M. J. Mehl
M. J. Mehl
M. J. Mehl
N. Binggeli
N. I. Papanicolaou
N. I. Papanicolaou
O. K. Andersen
R. N. Silver
S. H. Yang
W. B. Pearson
W. Kohn
Y. S. Touloukian
Y. Waseda
Publication date: 11 January 2001
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We studied the dynamical properties of Au using our previously developed tight-binding method. Phonon-dispersion and density-of-states curves at T=0 K were determined by computing the dynamical-matrix using a supercell approach. In addition, we performed molecular-dynamics simulations at various temperatures to obtain the temperature dependence of the lattice constant and of the atomic mean-square-displacement, as well as the phonon density-of-states and phonon-dispersion curves at finite temperature. We further tested the transferability of the model to different atomic environments by simulating liquid gold. Whenever possible we compared these results to experimental values.Comment: 7 pages, 9 encapsulated Postscript figures, submitted to Physical Review

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